Control system.



A. J. HALL. r

CONTROL SYSTEM. I

- APPLICATION FILED SEPT. 8. 1914. 1,241,507. Patented Oct. 2,1917.

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mvsu A/"fhu/"J. Hall.

By W A. l. HALL.

CONTROL SYSTEM.

APPLICAHON HLED SEPT. 8. 9H. 1,241,507. Patent/ed Oct. 2, 1917.

2 SHEETS-SHEET 2.

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ARTHUR J. HALL, OF WILKINSBURG, PENNSYLVANIA, ASSIGNOB TO WESTINGHOUSE ELECTRIC AND MANUFACTURING CGMPANY, A CORPORATION OF PENNSYLVANIA.

CONTROL SYSTEM.

Specification of Letters Patent.

Application filed September 8, 1914. Serial No. 860,607.

,To all whom it may concern:

Be it known that I, ARTHUR J. HALL, a subject of the King of Great Britain, and a resident of Wilkinsburg, in the county of Allegheny and State of Pennsylvania have invented a new and useful Improvement in Control Systems, of which the following is a specification.

My invention relates to control systems for dynamo-electric machines, and it has special reference to systems that are adapted to control the operation of electric locomotives or other railway vehicles that are propelled through the agency of polyphase induction motors which are governed by means of liquid rheostats.

One of the objects of my invention is to provide a system of control of the above indicated class which shall be simple in ar rangement and effective in operation, and which may be installed and maintained at relatively low cost.

Another object of my invention is to provide a system of the multi le-unit type adapted for train operation y means of which a plurality of polyphase induction motorsmay be arranged for different ranges of s cod and may be governed by a plurality of iquid rheostats throughout each speed range.

A further object of my invention is to provide a system of control for railway motors which shall be peculiarly adapted for the control of electric locomotives em ployed upon railway systems or electrified railroads having heavy grades and congested traflic, where severe service conditions are encountered and where economy of operation may be realized by the regeneration of energy to the distributing system on down grades or in stopping.

More specifically, an object of my invention is to provide a control system embodying a plurality of polyphase induction motors which may be adapted for difi'erent numbers of poles and for either cascade or parallel operation by means of a plurality of electrically operated speed-changing switches whereby several ranges of operating speeds are obtained, the acceleration of sald motors for each speed range being governed through the agency of a pair of liquid rheostats that are electrically controlled by a master controller, in a manner known to the art.

It is another object of my invention to simplify and improve the arran ement of circuits and mode of operation 0 a system of control of the type set forth in a copending) application, Serial No. 820 817, filed Fe ruary 25, 1914 by Benjamin Lamme and assi ed to the Westinghouse Electric & Manu acturing Company, and to provide adequate electrical means for actuating the switching devices and control apparatus and for controlling the operation thereof, and particularly to make provisions for interlocking the several correlated control devices, whereby a predetermined sequence of operation is insured and an improper order of operation is precluded. Thus, efficient and effective operation of the system is obtained without subjecting the apparatus to severe and damaging working conditions.

My invention may best be understood by reference to the accompanying drawings, in which Figure 1 is a view, in side elevation, of an electric locomotive for the control of which my system is adapted; Fi 2 is a diagrammatic view of a system 0 control embodying my invention, the main circuit connections and apparatus and the control switches which are directly associated therewith being shown completely, while the control circuits are omitted for the sake of clearness; Fig. 3 is a diagrammatic view of the control circuit connections and control apparatus including the energizing coils and auxiliary interlockin switches shown in Fig. 2. The interloc cing switches are distributed throughout the diagram for Simplification and clearness in lieu of being indicated in connection with the apparatus with which they are actually associated and by which they are actuated. By so doing, it is believed that a more ready understanding of the system and its mode of operation may be had, while unnecessary complications in the circuit connections are avoided. Figs. 4, 5, and 6 are simplified diagramamtic views, showin the arrangement of maincircuit connections of the motors for three different ranges of speeds.

I shall first set forth the main-circuit connections and apparatus and the choral mode of operation thereof, after which the control-circuit connections and operation will be discussed.

Referring to the drawings, the system shown is adapted for the control of a plurality of driving motors M1 and M2 that may be respectively associated with a plu- Patented Oct. 2, 1917.

jas

rality of driving trucks 1 and 2 of anelectric locomotive 3 and which, of course, is applicable to ditlerent: arrangements of motors, irrespective of the class of vehicles with which they are associated. The system comprises a plurality of supply-circuit conductor-s45, 6 and 7 which are adaptedto deliver polyphase alternating energy .to the polyphase induction motors M1 and M2; a plurality of line switches A1, B1, and C1 for connecting the supply. conductors -5, 6 and? to motor M1; a :pluralityof line switches A2, B2 and 'C2iinterposed between the Suppl circuit conductors and the motor M2; po e changeover switches PCO1 and PCO2-for arrangiig the winding connections of the motors 1 and M2 for different numbers of poles;.a cascadeswitch CS for connecting motors M1 and M2, either in cascade relationor in parallel circuit relation, a. plurality of liquid rheostats LRl and,LR2 adapted to be connected in the secondary circuits of the motors M1 and M2 forv governing the acceleration ,and operation thereof; an operating device OD for actuating the liquid rheostats LRl and LR 2; a plurality of switches X1 and Y1 for short-cir cuiting,rheostat'LRl, and switches X2 and Y2; for establishing short-circuit connections for. liquid .rheostat LR2.

Theniotors M1 and M2 are of the threephase wound-rotor induction type and respectively-embody primary windings P1 and P2. and secondary windings S1 and- S2. Initially, the windings are connected in-delta relation, and the external connections are made to the points of common connection, under\ which conditions, the motors are adapted for a particular number of poles, for instance, eight poles, while the windings are provided with taps at=substantially their mid-points, by means of which the number of poles of the motors may beihalved if desired, thereby producing four-pole machines. Inasmuch as these connections for adapting motors of this type for different numbers of poles are well-known, no further description thereof is deemed necessary.

The pole change-over switch PCOl com priscs a plurality of sets of main stationary contact terminals l0 and 11 and cooperating sets 12, 13, lit-and 15 of movable contact segments which are adapted to make on age ment therewith upon the position-in icatin lines 81 and4P, the change-over switch being adapted to occupy two positions, one for arranging the motor M1 for eight poles and the other for four poles. The switch PCOl embodies also a plurality of interlocking switches 20, 21, 22,123, 24 and 25 which comprise coo crating relatively movable contact termina s that arc-also adapted for on gagement upontlie position-indicating lines, hcrcinbefore referred to.

Each of the several interloclnswitches will be designated by a single reference numeral which indicates the movable conducting segment thereof, and for the sake of clearness, said switches will be hereinafter referred to by their numerals with the reference charac ter of the main switch with which they are associated and by the position ofsaid switch in which engagement between the cooperating members is effected. For instance, 23-- PCO18P indicates that conducting seg-J ment 23 of: pole change-over switch PO01 engages its stationary contact terminals when said change-over switch occupies its position 8P.

The switch PCOl is adapted to be electri cally operated by means of electromagnets 28 and 29, electromagnet 28 being provided with a single energizing coil 30PCO1- 4P,.and magnet 29 with a plurality of coils 31PGO18P and 32-PCO18P.

The pole change-over switch P002 is similar in construction to switch PCOl and embodies a plurality of sets of main stationary contact terminals 35 and36, cooperating sets 37, 38, 39 and 40 of movable conducting segments, a plurality of interlock switches 41, i2, 43, 44, 45, and -16, and a plurality of operating electromagnets 47 and 48', which, respectively, are provided with energizing coils 49PCO21P, 50- PCO2SP and 5lPCO28P.

The cascade switch CS" is also of similar construction to those just described and embodies a plurality of sets 55 and 56 of main stationary contact terminals, sets 57 5S and 58 of cooperatingmovable segments, a plurality .of interlock switches 59, 60, 61, 62, 63, 64, 65 and 66 and electromagnets 67 and 68, respectively, provided with energizing coils 69CS-ofl', 70-CS-ofi' and '71 CS0-n.

The liquidrheostat LRlcomprises a tank 7 5 having an inlet opening 76 through which electrolyte continuously flows, a. discharge opening 77 and a lurality of electrodes 78. Associated with t e discharge opening 77 are a plurality of concentrically related valves 81 and 82. The discharge valve 81 surrounds a tubular member 83 which is secured to the inner edges of the discharge opening 77 and is provided with a plurality of openings 83 near its lower end. and said discharge valve 81 is adapted to bernoved downwardly to close said openings 83. The valve 82 is the regulating valve and is slid ably fitted within the tube '83 and is adapted to be raised or lowered to affect the height of the electrolyte within the rheostat, itlbeing understood that the electrolyte is being continuously admitted into the rheostat and that the excess thereof, when the discharge valve'is closed, overflows through-said regulating valve 82 and the discharge opening 77. The discharge valve 81 is mechanically associated with a pneumatic operating. do

vice 86 which is conveniently supported by a member 87.

The operating device 86 comprises a cylinder 88 containing a movable piston 89 which is normally held in its upper position by a spring An electrically operated outlet valve 0V1 governs the admission of fluid thereto from a suitable source (not shown) and is provided with an interlock switch 85. The valve OV 1, when deencrgized, is closed and cuts off the supply of operating fiuid while establishing a communication between the cylinder 86 and the atmosphere, whereby its associated discharge valve 81 is held open.

Since the liquid rheostat LRZ is similar in all respects to the rheostat LRl, no description thereof will be given. The associated outlet valve 0V2 is adapted to control the actuation of the discharge valve 81 of rheostat L112, in the same manner as set forth in connection with rheostat LRl, and is provided with interlock switches 98, 99 and 100.

The regulating valves 82 of rheostats LRl and LE2 are mechanically associated'with the operating device OD. being connected to the ends of a common supporting member or arm 91 that is associated with a piston rod having end pistons 93 and 9t, which are movable within a plurality of operating cylinders 95 and 96, respectively. The lower end'of operating cylinder 96 is provided with an electrically operated valve marked On which, when deenergized, establishes communication between the cylinder 96 and the atmosphere and. when energized, admits operating fluid thereto. An electrically operated valve marked Oif is connected to the upper end of cylinder 95 and, when deenerg1zed, is open to admit operating fluid into said cylinder. Under normal operating conditions. therefore, when both the On and Off,m'agnet valves are deenergized, pressure isreleaSed beneath the piston 94; and is admitted above the piston 93, whereby the regulating valves 82 of the several rlieostats LRl and LE2 are biased'to and maintained in their lowest positions. When both magnet valves are energized, the re verse conditions are obtained, and the regulating valves 82 are moved upwardly. When only the On magnet valve is energized, balanced pressures are obtained on the opposite sides of the pistons 93 and 94, and the mechanism is maintained at rest. The operating device OD. as a whole, is termed a balanced-pressure operating device.

Associated with the operating device OD, are a plurality of interlock switches 101- LRup and 102LRup to cooperate with the cross arm 91 which operates the regulating valves 82. and said interlock switches are normally opened when the regulating valves 82 and the arm 91 are in their lowest positions and are subsequently closed by suitable means as soon as the cross arm 91 is initially raised. Another auxiliary interlock switch 103-L1tt0p is associated with the operating device OD and is arranged to be closed only when the cross arm 91 and associated regulating valves 82 are raised to their uppermost or top positions. The interlock switches associated with the outlet valves OVl and 0V2 are opened when their associated valves are deinergized and closed when their respective valves are energized and opened. Hereinafter, the several interlock switches referred to will be designated by their reference numerals together with the valve with which thev are associated and the position of the valve in which the switch is closed, as, for instance, interlock switch 1 00-0 V20pen.

Having set forth the arrangement of apparatus and the structural details thereof, I shall now describe, in a general way, the

main circuit connections, irrespective of the manner by which and in which said apparatus is actuated and controlled. v

Assuming the main circuit connections to be as shown in Fig. 2, the motors M1 and M2 are connected in cascade arrangement, with the secondary winding S2 of motor M2 connected to the secondary windings S1 of motor M1 and the primary windings P2 of motor M2 connected to the rheostat LE2. Moreover, the windings of the several motors are connected for their larger number of poles, namely, eight poles, andfhence, this cascade arrangement gives the equivalent of a sixteenpole machine, so far as the speed of operation is concerned. This constitutes the lowest-speed connection, which, it will be assumed, is adapted to produce a speed of approximately seven miles per hour.

In the co-pending application hereinbefore referred to, the pole change-over switches PO01 and P002 and the cascade switch CS and their circuit connections and mode of operation are fully described and, therefore, I shall not attempt to give a detailed description thereof nor to trace the main circuits which are mani ulated thereby. The switches PO01, PC 2 and OS are similar to the corresponding switches in the application to which reference has been made, except that they are provided with several auxiliary interlock switches and are operated electrically by means of suitable e.ectromagnets.

Having established the cascade connections of motors M1 and M2, outlet valve 0V2 is energized to effect the closure of the discharge valve 81 of rheostat LE2, under which condition the continuous flow of electrolyte into the rheostat raises the height thereof to the flush level, at which height the electrodes 78 are partially immersed and the excess of electrolyte overflows. Subsequent to the action of the outlet valve 0V2 and before the Hush level is established, the'line switches A1, B1 and C1 are closed to connect the supply line conductors 5, 6 and 7 to the primary windings P1 of motor M1. The motor-circuit connections are then as shown in Fig. 4.

The source of energy being thus connected' to the motors, said motors are started into operation and may be accelerated by gradually raising the level of the electrolyte within the rheostat LR2, whereby the resistance in the secondary windings S2 of motor M2 is gradually excluded. The ele-' vation of the electrolyte is, of course, efi'ected by raising the regulating valve 82 throu 'li the Balanced-pressure operating device'5D, it being understood that said device is caused to actuate said valve by enerizing the ofi andthe on magnet valves, wllerebyoper'ating fluid is admitted beneath piston 94 and released above piston 93. The movement of the valve 82, and hence motor acceleration, may be arrested by deenergizing. the oil valve, whereby balanced pressures, act'ing'upon the pistons 93 and 94, are obtained.

Havih raised'tlie electrolyte to its maximum-height, all the resistance is excluded from the secondary circuit of motor M2,

"and the sliort circuitin'gswitches X2 and Y2'are-closed. The full-speed operation for this'parti'cular connection of motors is thus obtained, namely seven miles per hour, and this is the first running position of the motors.

Tn order to'increase the motor speed, the valve; 0V2 is denerg'ized to permit the opening ofthe dischar e valve 81 of the rheostat LE2. The 0 and on magnet valves are also deenergi'z ed to permit the balanced-pressure operating device OD and its associated regulating valves to be lowered' to their initial positions, whereby the liquid rlieostat' LE2 serves to interrupt the motor circuit, after which line switches A1, B1 and C1 are opened.

Maintainin' the pole change-over switches PCQlan'd P 02in the same positions, the cascade switch CS is moved to its ofi position, whereby the motors M1 and M2 are connected'in parallel and-arranged for their larger number of poles, namely, eight poles. The outlet-valves 0V1 and 0V2 are then energized to effect the closure of the discharge valves 81 of the rheostats LRl and LE2, whereby the flush levels of the electrolyte are established. Prior thereto, however, line switches A1, B1 and C1 and A2, B2 and C2'are closed. Thus, energy is suppliedto the motors M1 and M2, which are connected in parallel and independently to rheostats LRl and LE2, the motor circuit connections being as shown in Fig. 5.

To increase the motor speed, the operating device OD is actuated to raise the regumemo? lating valves 82, whereby the electrolyte level is increased and the motor secondary resistances correspondin ly decreased until the maximum lieight oi the electrolyte is reached, when the short-circuiting switches X1, Y1 and X2 and Y2 are closed. The motors M1 and M2 are then connected in multiple to the supply circuit, with their larger number of poles, namely, eight poles. This is the second running position of the motors and the speed thereof is substantially double that of the first arrangement of motor-circuit connections, namely, fourteen miles per hour.

A still further range of operating speeds may be obtained by again emptying the rheostat's LR-l and LE2 of electrolyte and subsequently opening the several line switches, as hereinbefore described, after which the pole change-over switches PC( )1. and PCO2 are moved into their four-pole positions 4?, whereby the windings of motors M1 and M2 are rearranged to halve the number of poles, thus producing four-pole machines. The cascade switch CS remains in its oil position, whereby the multiple arrangement of the motors M1 and M2 is maintained.

Subsequent to arranging the motors for multiple operation and four-pole windings, the outlet valves 0V1 and 0V2 and the line switches A1, B1, C1 and A2, B2 and C2 are actuated in the manner already set forth. The motor connections are then as shown in Fig. 6. Energy is thus supplied to the motors M1 and M2, and they may be brought up to speed by raising the level of the electrolyte within the rheostats LRl and LE2 until the maximum hei hts are reached, when the short-circuit switches X1, Y1 and X2 and Y2 are closed. Under these conditions, the motors M1 and M2 are connected in multiple arrangement with four-poles, each with all their secondary resistance excluded. This is the third or full runningspeed condition and is adapted to efiect a speedof twenty-eight miles per hour.

It will be seen, therefore, that the motors may be arran ed for three ranges of operating speeds; rst, from zero to seven miles an hour, with eight-pole windings and cars cade arran ement; second, from seven, to fourteenmi es an hour, with eight-pole windings and multiple arrangement; and third, from fourteen to twenty-eight miles an hour, with four-pole windings and multiple arrangement.

Having considered, in a general way, the main motor-circuit connections and the mode of operation,-referenoe may be had particularly to Fig. 3' showing the auxiliary control-circuit connections which will now be discussed.

Among the control apparatus, is a master controller MC comprising two parts, a so called"speed drum SD and an acceleration drum AD. The speed drum SD comprises a plurality of stationary contact terminals LS', B, B+, LS-|-, AB+, 7' 14:, and 28, which are adapted to engage a plurality of movable conducting seglnents 110, 111 and 112 upon the positionindicating lines 7, 14 and 28, corresponding to the'several s eed connections, namely, seven, fourteen and twenty-eight miles per hour,"whereby the motor-circuit connections area'rranged for the different ranges of'operatingspeed s.

The accelerationdrum AD comprises a plurality of stationary contact terminals B"+, AB+, on" and by", which are adapted for cooperative engagement witha movable conducting segment 115 upon the osition-indicating lines marked Lower, Hold and'Raise, wherebythe action of the operating device OD that actuates the liquid rheostats may be governed at the will of the operator.

In order to adapt the system :for multiple unit train operation, a plurality of train line conductors B+, B,' LS, LS+, 7,, 14,, 28,, on and off are employed, and are severally electrically connected to the contact terminals of the speed drum SD and acceleration drum AD bearing corresponding reference characters.

Assuming the apparatus and circuit connections to be as shown in Figs. 2 and 3, the operation of the system is as follows: The speed drum SD is first moved into its position 7, while the acceleration drum AD is preferably caused to'occupy one of its operating positions marked Lower, whereby the motor-circuit connections are established for the first range of operating speeds, as shown in Fig. 4. In position 7 a circuit is completed, from the positive side of the battery B which includes train line conductor 13+, contact terminals B"+ and AB+, which are bridged by the acceleration drum conducting segment 115, contact terminals AB+ and 7,, which are bridged by a conducting segment 112 of the speed drum SD, train line conductor 7 and, providing the several pole change-over switches and cascade switch occupy their proper positions for efi'ectin a cascade arrangement of motor with 8 o e arrangements, a circuit is completed t n'ough interlock switches 21PCO1'8P, 44PCO2SP, 63-CS on, and thence, through energizin coil of outlet valve 0V2, to the negative side of battery B. The outlet valve 0V2, being thus energized, is actuated to'efi'ect the closure of discharge valve 81 of liquid rheostat LE2, and, in so doing, its associated interlock switch 100-OV2-open is closed. Thus, a circuit is completed from train line conductor 13+ which includes contact terminal B'+, conducting segment 111, contact terminal LS'+, train line conductor LS+, interlock switches 24PCO18P, 41- IC()28l, 61-CS-on, 100OV2ope'n 64-( Son, and line switches A1, B1 an ()1 to train line conductor LS- where the circuit is completed, through contact terminal LS' and B whichare bridged by conducting segment 110 of the speed drum SD to the negative side of the battery B; The energization of the coils of line switches A1, B1 and C1 effects their closure and connects the supply-circuit conductor-s5, '6 and 7 to the primary windings P1 of motor M1. It will be noted that interlock' switches 24, 41 and 61 of the respective speed-changin switches serve towinslire that" these switchin devices occupy their fullopera; tive positions before the line switches can be closed, thus preventing theconnection of the motors to the supply circuit in the event that some one of the speed-changing devices is out of order and is restrained in an inoperative position. Moreover, the interlock switch 64=CS on prevents the closure of line switches A2, B2 and C2 duringthe cascade operation of the motors. I

Having closed the discharge valve 82 of rheostat LE2, the continuously flowing electrolyte rapidly rises'in the rheostat until the tips of the electrodes 78 are immersed which is effected when the electrolyte raised to the flush-level. The timeinter val required for establishing the Hush:

level is sufiiciently long to enable'the closure of the line switches A1, B1 and C1 so that, as soon as the electrolyte is ,br'ou ht into contact with the tips of the electro es,

the motor-circuit connections are established. In order to start the motor into operation, the acceleration drum AD is moved into its raise position, whereby a circuit is established from contact' terminal B+. to include conducting segment 115, contact terminal on, train line conductor on, interlock switch '98?OV20pen and an energizing coil of the on magnet valve to the negative side of battery B. Another ,circuit is also established from the contact terminal B+ through conducting segment 115, contact terminal o}f", train line conductor off, interlock switch 99OV20pen and energizing coil of the OH magnet valve to the negative side of the battery.

Having energized the oil and on magnet valves, said valves' are actuated to respectively release the pressure from above the piston 93 0f,th'e operating device OD and to admit o crating fluid beneath the piston 94 thereo whereby unbalanced'pressure conditions obtain, and the regulating valve 82 of rheostat LR2 is raised into position. Obviously, as the regulating valve 82 is elevated, the level of the electrolyte within the rheostat LE2 is raised, inasmuch as it is continuously admitted thereto. Hence, the

motors M1 and M2 are gradually accelerated as the secondary resistance of motor M2 is gradually. reduced. 7

In case the desired speed is obtained, the operator has merel to move the accelerating drum- AD to its hol df position, whereby stationary t'erminal'ofi'" becomes diseng aged from conducting segment 115fand the. ofi magnet valve is deenergizedl'andpermitted to open. In so doing, fluid pressure is admitted to the upper cylinder 95;o'.'the operating device OD and'balanced pressure. conditions arenobtaihed, which. serve to, arrest further movementfof the regulatingvalve 82. If desired, the motor speed inay be decreased, by moving the acceleration .1 drum AD intolits l'ower? position, in which. contact terminal on'-' is.also-disengaged'.fiom contact segment'.l1 5 ,,wherel5y the .oril magnet valve is also de'e'nergiz'ed.andipermitted to close. Under'these conditions, thelower. cylinder '96 is exhausted suflicientlyto establish. unbalanced pressure relations tending to cause the movable art's of} device Oil to be forced' downwardly,.whereby the. regulating valve 82 of'rh'eostat-TRZ; is lowered. The electrolyte levelitherefore is correspond ingly lowered and the motor. speed? redilced, Assuming that the acceleration (h-11mm); occupies its raise positionfthe upward. movement of the operating device QDland thereg'ulating' valve lco'ntini 's-,ui t' Qthe. maximumheight is reached: en the arm. 91' of the operating device ODQattaiiis its uppermost position, or jus't prior thereto,.it engages interlock switch 103-LR ,'-top, and; effects the closure thereof, Thereupom. acircuit is completed from the negative side of interlock switch 63 -,CS'on, which iiicludes interlock switch 103-L R -togz and. energizing coils of the short-circiiitswitches X2 and Y2, to the negative side ofthehatetery. These switches are,,therefore, en'ert gized and closed to establish short ciicuit connections between the severalelectrodes' 'l'By of the rheostat LE2, while interlock: switch.- 65OS--0fi prevents the actuation of. the

short-circuit switches X1 and Y1. dii-riiig cascade 0 eration, inasmuch as the cascade switch C occupies its on position.

In order to further increase the motor speed, it is necessary to re-arrange the connections of the motors M1 and M2, 51nd,} hence, the speed drum SD is m0vedto its position 14. During this movement; the contact terminal 7 becomes disengaged from conducting segment 112-, thereby deiinergiw in outlet valve 0V2 andshort-circuiting switches XQJandYQ; Hence, the discharge. valve 82 of rheostat LE2 is opened to permit the discharge of electrolyte therethrough, while the several interlock switches associated with the valve 0V2 are caused tointerrupt. their control circuits. The' shortcircuit switches X2 and Y2 are also dese rgizediand opened. As the interlock-switches 98OV2-.-.open| and, 99-'iOV2:0pen interruptthe ener izin circuits ofthe respec tive on an 0% magnet valves, said valves arereturned totheir initialvpositions, whereby. unbalanced pressures are-obtained which. act. upon the movable parts of the ofiieratin'g. device: OD to return them and t eirfassociated regulating valves 82 :to their lowermost positions. During the i lowering of the regulating. Valves 82, the. interlock switch 102.-LR 'wp' is maintained. closed until the operating device OD reaches sub.- stantially its.- lowermost position. Therefore,- [the line switches A1, B1 and. are heldlclosed" until the interlock switch,.just referiedlto, isopenedv by. reasonof engagementof'arm 91I therewith inrits lowest posi tion.

Concurrently with. the. lowering Of! the operating.,,device OD- and. regulating. valve S2,,the electrolyte withinthe rlieostat LR2 is being rapidly discharged; which action is completed before the regulating; valve 82: is completely loweredi and; the line switches A1, B1 and G1 opened. Therefore, the interrnption. ot'thev motor. circuits is effected by the. electrolyte within the rheostat, and the line; switches merely. serve to subs-eque'ntly disconnect themotorfi-om the supply circuits.

As soon as-the line switclies'are opened, a circuit i'sconrpleted 'fitomispeed.drinncontact termihal'A'B through oondu ctingisegmenti 112, contact terminal 14",, train line com ductor 14,, interlock switches Biz-out and El -out energizing, coil' 69-CS--0n and interlock-switch;59CS0n to the negative side of the battery. Thecascade switclnCS, therefore, is actuated to its off position, \i'hereby, the motors M1 and Mil are connectediih multiple relation, and thecascade or.- rangement thereof is discontinuedl. No changesare effected in the arrangement of the motor windings and, therefore, the-mm tors are still connected for eight poles.-

, Upon-the movement of the cascade switch.

GS to its ofl'P'position, a circuit is completed from the train line conductor 14;

through interlock Swim1ies.22 roo1 s1 45PCO28P, 60CS 0/f., and energizing-coil of outlet'valve OV2to the B- train line conductor. The establishment of the circuit'just'traced'efleots the actuation of'thevalve 0V2, whereby the discharge valve 81 of rheostat LE2 is closed The discharge valve-of rheostat LRI' is alsoclosed concur.-

rently therewith, inasmuch. as outlet valve.

diict'or LS+ through interlock switches lso 24=-PCO1-8P, 41PCO2-8P, and 66 CSofl', where the circuit divides, one branch traversing interlock switch 85 OVl-open and the energized coils of line switches A1, B1 and O1 to train line conductor LS, and the other branch including interlock switches 10()OV2-0pen, and G4-CS-0 and energizing coil of line switch A2, B2 and C2 to the LS train line conductor. The several line switches A1, B1, C1 and A2, B2 and C2 are, therefore, energized and closed to connect the several motors M1 and M2 in parallel relation to the supply circuit conductors 5, 6, and 7, as shown in Fig. 5. During the closure of the line switches the continuously inflowing electrolyte establishes the flushlevels and starts the motors into operation.

The energization of outlet valve 0V2 effects the closure of interlock switches 98OV2-0pen and 99OV20pen, and, inasmuch as the accelerating drum AD still occupies its raise position, the magnet valves on and oil are energized. Consequently, the operating device OD is caused to raise the several regulating valves 82 of the rheostats LRl and LE2.

As already set forth, the initial movement of the arm 91 permits the closure of interlock switches 10lLR-up and 102LR up whereby the energizing circuits of the line switches are maintained until the regulating valves 82 are again lowered to their initial position.

Manifestly, the level of the electrolyte within the rheostats LRl and LR2 may be governed at the will of the operator by moving the accelerating drum AD into the proper positions. The speed of the motors, therefore, is at all times under control. No description of the manipulation of the accelerating drum AD and corresponding operation of the operating device OD and rheostats LRl and LE2 will be given, inasmuch as the functioning of the apparatus is similar to that already described in connection with the cascade arrangement of the motors.

Assuming the accelerating drum AD to be maintained in its raise position, the several regulating valves 82 of the rheostats Llll and LE2 are gradually raised until their maximum positions are reached. Just prior thereto, interlock switch 103LRtop is closed by reason of the engagement of the arm 91 therewith, and thus, a circuit is completed from the negative side of interlock switch CSo/f through interlock switch 103LR-zfop where the circuit divides, one branch traversing the energizing coils of short-circuit switches X2 and Y2 to the B- train line conductor and the other branch traversing interlock switch -OS- of) nndenergizing coils of short-circuiting switches X1 and Y1. Said switches, therefore, are actuated and closed to short-circuit the several rhcostats when they have performed their functions of completely eliminating the motor-secondary resistances.

If it is desired to further increase the mo- .tor speed, the speed drum SD is moved to position 28, contact terminal 14', being thus disengaged from conducting segment 112, whereb the short-circuitswitches X1, Y1, X2 and Y 2, and outlet valves OVl and 0V2 are deenergized and are caused to return to their initial positions. The deenergization of outlet valve 0V2 causes the interlock switches 98OV2open and 99-OV2 open to interrupt the energizing circuits of the on and off magnet valves, whereby the operating device OD and associated regulating valves 82 of the several rheostats are moved to their lowest positions, while the electrolyte within the rheostats is being discharged through the opening of the dis charge valves The motor circuit connections are thus interrupted through the electrolyte within the rheostats during the transition from one motor-speed connection to another. As soon as the regulating valves 82 reach their initial ositions the interlocking switches 101-Llup,- and 102LR up are disengaged and caused to denergize the several line switches which open to disconnect the motor from the supply circuits.

Immediately following the opening of the line switches, a circuit is established from the speed drum SD through contact terminal 28 train .line conductor 28,,interlock switches C2out and C1out and thence, in parallel, through one branch including energizing coil '30-POO1--8P to the battery and through energizing coil 49POO28P to the battery. The pole change-over switches PCOI and PO02, therefore, are actuated into their 4P positions, whereby the motor windings are reconnected and arran ed for four poles. The cascade switch Cg remains in its off position so that the motors M1 and M2 are connected in multiple relation, with four poles instead of eight poles.

As soon as the switches PCOl and PO02 occupy their 4P positions, a circuit is established from train line conductor 28 which includes interlock switches 20POO14P, 43-POO24P and 60CS'o f and thence, through the energizing coils of outlet valves OVl and 0V2, in multiple, to the battery, interlock switch 62OS-ofi being closed to complete the circuit through the coil of valve OVl. The several discharge valves 81 of the rheostats LRl and LE2 are, therefore, closed and the electrolyte rises rapidly within the rheostats to establish the flush-levels.

Inasmuch as the rest of the operation and circuit connections are similar to those al ready described in connection with the secend-speed osition 14 of the speed drum SD, no urther description thereof is deemed necessary.

I It will be understood, however, that, as soon as the valves 0V1 and'OVE are open, their associated interlock switches close to initiate the operation of the operating device OD-and to eifect=the closure of the line switches A1, B1 and Gland A2, B2 and 02. Having established the" motor circuit connections for the third-running speed, or the 28 position of the speed drum, as shown in Fig. 6, the further control of the motors by means of the accelerating drum AD maybe governed in aocordance' with'thewill of the operator, as already describedin detail.

The operationof the system may be discontinued at any time by moving the speed drum SD -or the acceleration drum AD to their respective oil positions, this movement of the acceleration drum' serving to interrupt the motor circuits by the insertion of resistance into the secondary windings and Lfina'lly interrupting through the electrolyte, as is accomplished through transitions from one speed connection to'another, and the movement of the speed drum eflecting theinterruption of the motor circuits through the opening of the line switches.

In order to decrease the speed of the motors Ml and M2-from one of the higherspeed positions ofthe speed drum 'SD, the operation is substantiallylik'e'that described heretofore and merely necessitates the manipulation of the speed drum SD to the desired lower-speed position, which causes the electrolyteto be emptiedfrom the rheostats, the line switches to be opened, the pole change-over and cascade switches to be moved to their proper positions, and subsequently the motors reconnected to the source and the operation resumed, during which action, energy is regenerated to the supply circuits so long as the motor speed is in excess of the synchronous speed corresponding to the particular motor connections.

This system of control is particularly adapted for the utilization of driving motors M1 and M2 as generators, being riven by the inertia of the vehicle or locomotive for the regeneration of energy to the source. The regenerative action of the motors may be efiected at any time when the speed thereof is greater than the normal speed of the motors corresponding to the particular arrangement of motors and circuit connec tions established. If, therefore, the motors are running at substantially twenty-eight miles per hour and it is desired to retard or stop by breaking dynamically, the speed drum SD may be moved to its second position 14 which establishes the motor connections for the fourteen mile per' hour operc5 ation, whereby regeneration of energy is effccted until the speed has been reducedrto substantially fourteen miles per hour. During the regeneration 'the operation of the liquid rheostats is identical with that hereinbefore described, that is, the rheostats are initially emptied and are subsequentlyfilled gradually in accordance with the manipulation of the accelerating drum AD.

Further regeneration may be effected after the speed has been reduced to substantially fourteen miles per hour by moving the speed drum SD to its position 7, whereby the motor connections are rearranged for the seven miles per hour operating speed, after which the regenerative action maybe utilized until the motor speed has'been reduced to that corresponding to the synchronous speed of the motors in the position 7 of the speed drum.

Obviously, my invention is not restricted to the structural details and the specific arrangement and location of parts and circuit connections herein set forth, and many modifications therein may be effected without departing from the spirit and scope of my invention.

I claim as my invention:

1. In a control system, the combination with a source of energy, a plurality of polyphase motors, and means for connecting said motors to said source, of a plurality of switching devices for ariangin the circuit connections of said motors For different ranges of operating speeds, and means for preventing the operation of said switching devices when said connecting means is in its closed position.

2. In a control system, the combination with a source of energy, a plurality of polyphase motors, and means for connecting said motors to said source, of a plurality of switching devices for arranging the circuit connections of said motors for diflerent ranges of operating speeds, and electrical means dependent upon the positions of said connecting means for controlling the actuation of said switching devices.

3. In a control system, the combination with a source of energy, a plurality of polyphase motors, and means for conncctin said motors to said source, of a plurality of electrically operated switching devices for arranging the circuit connections of said motors for different ranges of operating speeds, and auxiliary interlocking switches associated with said connecting means for preventing the operation of said switching devices when said connecting means is closed to supply energy to said motors.

4. In a control system, the combination with a source of energy, a plurality of polyphase motors, and means for connecting said motors to said source, of a plurality of electrically operated switching devices for arranging the circuit connections of said motors for different ranges of operating speeds, and means coiiperating with said switchingdevices forpreventing the actuation thereof when energy is supplied to said 5, In a control system, the combination with a souroe-ofenergy, a plurality otpolyphase motors, and-means'for connecting said *motois 'to said source, of a plurality of loswitching devices 'for' changing the number of poles (if said motors, and "a switching device for connecting said motors cascade or in parallel relation," hereby-said motors are adapted for different ranges (if-operating speeds, electrical means 'for controlling and operating said switching devices, and interlocking means associated with said con necting means'for preventing "the actuation of said switching devices when said connecting means is closecl'to supply energy'to said n'iotors.

"6. In a control system, the combination n'itlra source of energy, a polyphase motor adapted'tolbe connected for different num- 3 hers-dipoles, and means'forconnecting said motor to said source, of electrically operated pole-changing switching means'for adjusting the pole connections of said motor,

and meansassociated with said connecting means for preventing theoperation of said pole-changing switching means when said connecting means is closed.

7. In a control-systenn't-he combination with a source of energy, a.plnrality (if-polyihase motors, and switching meansfor connecting-said motors to said source, of an electrically operated switching device for arrangingsaid lnotorsinparallel or in cascade relation, and interlocking means asso- 4 ciated with said switching means for prerentingthe actuation of said switching 'derice'whenenergy issupplied to said motors. v 8. In a control system, the combination with a source-of energy, aiplurality of polyphase motors 'aila ted 'to receive energy therefrom, and a p urality or switching de- "ices for arranging the motors for different ranges of operating speeds, of .means for governing the operation of said motors for each range of speed, and meansforjpreveuting'the operation of said governing means until 'said'switching devices occupy predetermined positions.

'9. In a control system, the combination with a source of energy, a plurality ofpolyphase motors adapted 'to receive energy therefrom, and. a plurality ofswitching devices for arrangmgthe lnotors for different ranges of operating speeds,=of means for governingthe'operation of said motors'for each range of speed, and interlocking means associated with said switching devices for permittin the operation o f'sai'd governing means on y when. said switching devices oocupy predetermined positions.

10. In control system, the combination with a source of-energy, a plurality of polyph-ase motors adapted to receive. energy therefrom, and a plurality of switching devices for arranging the motors fordifi'erent ranges of operating speeds, dielectrioally controlled means -f or governing theacoeleration of said motors throughout each spee}i A range,

and interlocking switches-associated with said 'Switchin devices for preventing the operation of said accelerationgoverning means when said switching devices'oocupy imp roper, positions.

1l. In a control with a source of en systein, the; combination ergy, apluralityof polyphase' motors adapted to receive energy therefrom, and a plurality of-switchin g-derices -for arranging the-motors :for different ranges of operating speeds, ofanelectrically controlled liquid rheostatifor. governingthe acceleration of said motors for" each speed range and having a control circuit interlocked with certainpositions of'saidswibchng devices, whereby saidrheostat is operative only when said-switching devices-are. in predetermined positions. a i

'12. In a control system, the'combination with a source of polyphase motors energy, a .Plflrzility of receiving (energy ,therefrom, a plurality ofpoIe-ichanging switches for adapting said. motors j'fondfii'erent numbers of poles, and

another iswitch lfor econnecting said motors'in. arallel or in cascade relation, whereby i'fierent ranges of operating speeds are obtained, ofa,plura1i ty of rheostatic devices 'for governing the-acceleration of said range of speeds,

motors throughout each electrically controlled means for actuating said rheostatiodevices, and Interlocking means permittin theenerglzation of said electrlcally contro led means only when said pole-changing switches :and

said cascade switch occupy predetermined relative positions.

13. Ina control system, the comhination -\\'ith a source of energy, aplurality of .polyphase motors receiving energy .therefromva plurality of pole-changing switches for adapting said motors for different numhers of poles, of operating for governing whereby a plurality of: ranges speeds is obtained,. and. means the acceleration of said-motors 'for each range of speed, of .means for rendering the operation of said governing meansdependent u on predetermined .positions of saidpole- 14. In a control c ianging switches.

system, the combination with a source of energy, a plurality o f polyphase motors receiving energy therefrom ia plurality of pole-changi switches for adapting said motors for different numbers of ,poles, whereby a plurality of ranges of operating speeds is obtained, and means..for governing the acceleratlon'of said motors for each range 0 f speed, of interlocking means associated with said pole-changing switches for permitting the operation of said acceleratlon governing means only when said switches occupy corresponding positions.

15. In a control system, the combination with a source of energy, a plurality of polyphase motors, and means for connecting said motors in cascade and in parallel relation for diiferent eed ranges, of a plurality of rheostatic devices for governing the operation of said motors and means for permitting the operation 0 only one rheostatic device when said motors are connected in cascade arrangement.

16. In a. control system, the combination with a source of energy, a plurality of polyphase motors, and speed-changing means for connecting said motors in cascade and in "parallel relation for different speed ranges, of a plurality of rheostatic devices for governing the operation of said motors, electrical means for controlling the operation of said rheostatic devices, and interlocking means associated with said speedchangmg means'and adapted to govern the action of said electrical controlling means for permitting the operation of both rheostatic devices when the motors are arranged in parallel and of only one rheostatic device 'when, arranged in cascade.

17. In a control system, the combination with'a' source of energy, a plurality of polypliase motors, and means for connectin said motors in cascade and in parallel re ation fordifl'erent speed ranges, of a plurality of liquid rheostats for governing the acceleration of said motors and severally having electrically operated discharge valves, an means for preventin the actuation of one of' said discharge va ves when said motors are connected in calscade arrangement.

18. In a control system, the combination with a source of energy, a plurality of polyphase motors, and means for connecting said motors in cascade and in parallel re ation for different speed ranges, of a plurality of liquid rheostats for severally governing the acceleration of said motors when connected in parallel, andlmeans for preventing the operation of one rheostat when said motors are connected in cascade relation.

19. In a control system, the combination with a source of energy, a plurality of polyphase motors connected thereto, a switching device for connectin said motors in cascade andin aralle relation, and a pluralit of switc 'ng devices for changing the num er of poles of said motors, whereby difierent ranges of operating speeds are obtained, of a plurality of electrically controlled rheostatic devices for severally governing the acceleration of said motors. and interlocking means associated with said casceding switch for preventing the operation of one of said rheostatic devices when said motors are connected in cascade relation.

20. In a control system, the combination with a source of energy, a plurality of polyphase motors connected thereto, means for connecting said motors in parallel'and in cascade relation, and a plurality of rheostatic devices for governing the acceleration of said motors, means for short-circuiting said rheostatic devices in 'their full operative positions, and means for preventing the short-circuiting means of one rheostatic device'from operating when the motors are connected in cascad relation.

21. In a control system, the combination with a source of energy, a plurality of polyphase motors connected thereto, means for connecting said motors in parallel and in cascade relation, and a plurality of rheostatic devices for overning the acceleration of said motors, 0 means for short-circuitingsaid rheostatic devices in their full operative positions when the motors are connected in parallel, and men ns associated with said connectin of said short-circuiting means from acting when the motors are connected in cascade relation.

22. In a control system, the combination means for preventing one with a source of energy, a plurality of polyof said motors, of means for short-circuiting 37 said rheostatic devices, means for preventing the operation of said short-circuiting means until said rhcostatic devices occu y their full operative positions, and means or preventing the short-circuiting means of one j rheostatic device from acting when said motors are connected in cascade arrangement.

23. In a control system, the combination with a source of energy, an electric motor connected thereto, and a liquid rheostat for governing the operation of said motor and having a discharge valve and a regulating valve for fixing the height of the electrolyte.

of menus for preventing the actuation of said regulating valve until said discharge valve occupies a predetermined position.

24. In a control system, the combination with a source of energy, an electric motor connected thereto, and a liquid rheostat for governing the operation of said motor and having a discharge valve and a regulating valve for fixing the height of the electrolyte, of interlocking means associated with said discharge valve for permitting the operation of said regulating valve only when said discharge valve is closed.

25. In a control system, the combination with a source of energy, an electrical motqr connected thereto, and a liquid rheostat for when said disc fluid-o eratedpiston wot-king within a cylinder avin'g a-plorality ofelectromagnetic valves normally adapted to'admit opereting fluid thereto to causesaid reguletin valve to be movedto itsofi position, 6 means for tiecnergi'ziniasaid' electromagneticvalves v rge velve'i's'op'en to "discharge electrolyte from "said 'rheostiit, where!) said regiilaiting'valve is retumed to its off "position.

' 26. In a control "systemitlre combination -'-;witha. source of energy, a p'olypha'se induc- 'tion 'motor connected thereto, and "a switching device for amnging the motor connec- 'tions for -diflerent "ranges of "operating speeds, of a liquidn-i ieosrst for governin the acceleration of said motor and embodying an electricdlly-operate'ddischarge vdl've,

a reguiating-valve'adoptcdtofixtheheigiit of the electrolyte, end an lectricalIycon- 3 trolled de'ice for actuating "said valve, means fox-preventing the pperction o'f"said 'electrically cbntrolled'Heviceuntilsaid discharge vsilveoccupies its closed position.

27. In a control system,"thecoinbintion with'ii source of energy, apolyphase induction motor, a switching device for'conne'cting said motor to said sou rce, and s liquid 'r'h'eo'stiit' for 'gbverning't'he o erationofsaid motor and embodying a -egii1=iting'-v'=ilv e for fixing the height of the electrolyte, of

means iiss'ocisted' withsaid'regqisting valve for'eiiectin "-the *interruptionof the motor circuits Wit in said rheostalt.

- 28. In'a control system, "the combination with a source ofener'gy, a polypha's'e induction motor, and a switching devicefor'c'o'nnecting said motor tosai'd source, o'f'arheostatic device for governing the acceleration (if said motor, electrically controllcti'meons associated with said rheostatic de'yice for actuating "said device, and interlocking means associated 'with' said 'le'ctri'csilly controlled means for causingthe'interruption of'the motor circuits to'hee'fl'ete'd by said rheosta tic device. I

29. In a control system, the'combinetion with a source of energy,ja polyphaseinduction motor, a. switching'dcvice for connecting the motor to"said source, and an'electrically-controlled liquid rheostat for'governing the acceleration of said motor andf'embodying' aiiisch'at; e vs l've and a 'regilleting valve edapted'to cruisednnd lowered "to fix the hei 'ht'ofthe'electrolyte,of an interlock switch 'asscciiited "with said ;rheostat and adapted to be actueted When'said"regulating 'valve in its lowest position for maintainingsaid switching'device closed until said regulating vaflve occupies its 'lowe'st position.

330. In a system 'of controL-the combination with a sourceof'cncrgy, a plurality of poly'phose induction motors "a; plurality of electrically-operiitetl switches "for connecting 'saiii "motors to said source of energy, "and "a pluriility' of Speed-changing switches for arranging the motor connectionsfor different'ran es ofoperztting'specd, of a )lurdlityof e ectrically controlled'liquid r eosta'tsfor governing'the acceleretiono'f said motors-'andembodying discharge valves and 'regnlziting valves for'raisifn'g and lowerin the'height'of the elcctrolyte'therein, an" means associated with 'said rheostats and 'governin theoperation o l-said line switches or cons ng the interruption of 'the motor circuits to occur Within said "rheostats when the transition from one speed to another is effected by said speed-changing switches.

'31. In a control'system,the;combina tion uith asour'cedf'ener'gy, aplnrzility of polyplm-se induction'motors,a plurality of electriczilly op'erated line "switches for connectsaid motors'to said sourcc,'and-'apinin rafity of "switching devices for an-angin the 'motor circuit connections 'for paiiille 'an'd for-cascade operiition "whereby different ranges ofopertingspee s'are'obtained, of "a' plurality of liquidrheostatsseverally havin'g'dischar' e valves "and regulating Valves "adapted "to e raised and lowered 'for'fixing the hei htof'the'lectrolyte, an electrically- ;control e'd operating device'for said regulatin ralves', meens for controlling'the op'cratlon df'sai'd operatin device, and interlocking means actuate by said operating device for maintaining sai'd line switches in their "closed positions and permitting the interruption of the motor circuits to be efie'ted within said'rheostats when the'transition between the different speed connections of said 'motorsis effected. g

"32. Ina control s'ystem,the combination with a source of eneriy, a polyphaseinduction'motor adapted to e connected for a plu- 'ra'.lity of ranges 'of'opereting speeds, and liquid'i'heostats'for governin the acceleration of'saidmotor dnringeac speed range, of line switching devices for connecting said motorsflto said source, and means for ofline switching devicesfor connecting said motors'to said source, andme'ans for causing). said rheostats and said line switching devicestosuccessively open'the motor circuits.

3'4. -In' a control system, the combination with"a'source'ofenergyfa'polyphase inducphase electric motors,

switching device for to said source, and a said motor and emerning the operation of bodying a regulating valve adapted to be raised and lowered for fixing the height of the electrolyte, a discharge port and a discharge valve for opening and closing said discharge port, of electrically-controlled means for actuating said regulating valve,

means associated with said discharge valve for efl'ecting the closure of said line switches subsequent to the closure of said discharge valve and prior to the operation of said regulatin valve operating means.

36. n a control system, the combination with a source of energy, a polyphase induction motor, electrically-operated' line switches for connecting said motor to said source, a liquid rheostat for governing the operation of said motor and embodying a discharge valve for controlling the discharge of electrolyte from said rheostat, and

an electrically-controlled regulating valve adapted to be raised and lowered for fixing the height of the electrolyte, of interlocking means associated with said discharge valve for efi'ecting the closure of said line switches subsequent to the closure of said discharge valve, and other interlocking means associated with said discharge valve for delaying the operation of said regulating valve until said discharge valve is closed.

37. In a control system, the combination with a source of energy, a plurality of polyphase induction motors, electrically-operated switches for connecting said motors to said source, a plurality of liquid rheostats for governin the operation of said motors, and controlla le means for governin the operation of said rheostats, of a plura ity of electrically-operated speed'changing switches for arranging the motor connections for parallel and cascade operation, whereby different ranges of operating speeds are obtained, means associated with said controllable means for causing said line switches to interrupt the motor circuits when said means is moved to its off position, and means associated with said liquid rheostats for causing said rheostats to interrupt the motor circuits durin the transition effected by said speed-changing switches.

38. In a control system, the combination with a source of energy, a plurality of polyand a plurality, of

switching devices for connecting said motors to said source, of a plurality of s cod-changing switches for connecting sai motors in parallel and in cascade relation, and means for preventing the closure of one of said motor-connecting switching devices .when said motors are connected in cascade relation.

39. In a control system, the combination with a source of energy, a plurality of polyphase induction motors, and a plurality of electrically-operated line switches for conneeting said motors to said source, of a plurality of speed-changing switches for arranging the motor connections for parallel and cascade operation, and interlocking means associated with one of said speedchanging switches for preventing the closure of one set of motor line switches when said motors are connected incascade relation.

40. In a, system of control, the combination with a source of energy, and a plurality of polyphase induction motors adapted to be connected in parallel and in cascade relation, whereby aplurality of operating speeds are obtained, of interlocking means for preventing the closure of one set of line switches when said motors are connected in cascade arrangement.

41. In a system of control, the combination with a source of energy, a plurality of polyphase induction motors adapted to be connected for diflerent numbers of poles, and a plurality of switching devices for arranging the motor connections for different numbers of poles and for connecting said motors in parallel and in cascade relation, of a plurality of line switches for connecting said motors to said source, and means for preventing the connection of one of said motors to said source when said motors are connected in cascade relation.

42. In a system of control, the combination with a source of energy, a plurality of polyphase induction motors, a plurality of switching devices for connecting said motors fordifierent numbers of poles, and a switching device for arranging said motors in parallel and in cascade relation, of a plurality of electrically-operated line switches for connecting said motors to said source during parallel operation, and interlocking means associated with said cascade switching device for preventing the closure of one set of line switches when said motors are connected in cascade relation.

43. In a system of control, the combination with a source of energy, a plurality of polyphase induction motors adapted to be connected for difierent numbers of poles and in parallel and in cascade relation, and a plurality of switching devices for arranging the motor circuit connections in said relations, of a plurality of line switcheg adapted to connect said motors to said .cu py. their .operative source, and meansfor precluding the, clos- .ure of said line switches until said devices occupy their-operative positions.

44. Inasystem oficontrol, the combination-witlra. source of energy, a plurality of motors and a plurality ofswitching denecting said. motors to said source and interlocking means associated with said switching devices for preventing the closure of said line'switchesuntil suiddevices ocpositions.

45..In a system ofcontrol, the combination with a,source .of encrgy,a plurality of polyphaseinduction motors, and aplurality of switching. devices. for. connecting said motors for difierent .niimbers of :poles, of a plurality of electrically-operated line switches for connecting said motors to said source and interlocking, means associated with.said switching devices for preventing the closure of said electrically-operated line switches until all ofsaid switching devices occupy their operative positions.

46. In aisystemof control, the combination with a source of. energy, a. plurality of .polyphase induction motors, and a pluralityof electrically-operated. line switches for con.- nectingisaid motors to said source, of a plurality of switching devices forLarranging the.- circuit connections of said motors for diiferentnumbers of poles, another switching device for connecting said. motors in parallel and in cascade relation, and a plurality of interlocking means associatedwith saidswitching devices and adapted to govern the operation of said line switches, whereby said line switches can be closed only when -said..switching .devices occupy predetermined positions.

47. In a systemof control, the combination with a source of energy, aplurality of polyphase induction .motors, and a.plurality of line switches for connecting said motors to said source of energy, of a plurality of speedschanging switching devices for arranging the motor-circuit connections for different numbers of poles and for parallel and, cascade operation, whereby; diiierent ranges of operating speeds are obtained, andia plurality of interlocking means associated with the several speedschanging switches for preventing the energization and closure of said line switches when said speed-changing switches are out of their operative positions.

48. In a system of control, the combination with a source of energy, a plurality of polyphase induction motors, a plurality of electrically-operated line switches for connecting said motors to said source, a plurality of speed-changing switches for conactuating its switch in the o necting said motors for different ran es of operating speeds, and a plurality of iquid rheostats for governing the acceleration of said motors, of a master controller for controlling the operation ofsaid speed-changing devices and said line switches,'and a second master controller for controlling the operation of said liquid rheostats, said first controller being adapted to effect the interruption of said motor circuits through said line switches when moved to its oil position, and said second controller being adapted to effect the interruption of said motor circuits through said liquid rheostats when moved to its oif position.

49. Ina system of control, the combination with a source of energy, a plurality of polyphase induction motors a plurality of electrically controlled spec changin' de vices for arrangin said motors for iiferent numbers ofpo es and for cascade and ,parallel operation, a plurality of electrically operated line switches for connecting said motors to said source, and a plurality of electrically controlled liquid rheostats for controlling the acceleration of said motors, of a master controller for controlling the operation ofsaid speed-changing devices and said line switches, and 'a second master controller for controlling the operation of said liquid rheostats, said ,first master'controller being' adapted to cause said line switches to interrupt themotor circuits when said controller is moved to its oifposr tion, .and said second master controller to cause said liquid rheostats to effect the interruption of said motor circuits when said controller is movedto its off position.

50. In a system of control, the combination. with a source of energy, a plurality of polyphase induction motors, and a plurality of electrically operated speed-changing switches for arranging the motor connections for-difierent ranges of speeds and each embodying an operating electromagnet for actuating its switch in one direction and a plurality of operating electromagnets for posite direction, of controllable means or-governing the energization of said electromagnets.

51..In asystem of control, the combination with a source of energy. a plurality of polyphase induction motors, and a plurality of electrically operated speed-changing switches for arranging the motor connections. for different ranges of speeds, and each embodying an operating electromagnet for actuating its switch in one direction and a plurality of operating electromagnets for actuating its switch in the opposite direction, of a master controller for energizing corresponding operating electromagnets associated with each of said speed-changing switches for effecting the transitions from one motor-speed connection to another.

52. In a system of control, the combination with a source of energy, a plurality of polyphase induction motors, and a lurahty of electrically operated speed-c anging switches for arranging the motor connections for different ranges of speeds and each embodying an operating electromagnet for actuating its switch in one direction and a plurality of operating electromagnets for actuating its switch in the opposite direc* tion, of a master controller and as many control circuits as there are electromagnets for each speed-changing switch for concurrently energizing corresponding electromagnets associated with the several switches for actuating said switches from one position to another to effect transitions of speed connections.

53. In a system of control, the combination with a source of energy, a plurality of polyphase induction motors, and a plurality of electrically operated speed-changing switches for arranging the motor connections for different ranges of speeds and each embodying an operating electromagnet for actuating its switch in one direction and a plurality of operating electromagnets for actuating its switch in the opposite direction, of interlocking means associated with the several speed-changing switches for arranging the energizing circuits of said operating electromagnets in accordance with the relative positions of said speed-changing switches, and controllable means for go"- erning the energization of said electromagnets.

54. In a system of control, the combination with a source of energy, a plurality of polyphase induction motors, and a plurality of electrically operated speed-changing switches for arranging the motor connections for difierent ranges of speeds and each embodying an operating electromagnet for actuating its switch in one direction and a plurality of operating electromagnets for actuating its switch in the opposite direction, of a controller having a lurality of operative positions for severe y energizing corresponding electromagnets of each speed-changing switch, and interlocking means associated with said speed-changing switches for arranging the circuits of the electromagnets to be energized in accordance with the positions of said speed-changing switches.

55. In a system of control, the combination with a source of energy, a plurality of polyphase induction motors, and a plurality of electrically operated speed-changing switches for arranging the motor connections for different ranges of speeds and each embodying an operating electromagnet for actuating its switch in one direction and a plurality of operating electromagnets for actuating its switch in the opposite direction, of controllable means for governing the energization of said operating electromagnets, and means for insuring their energizetion in a predetermined sequence.

56. In a control system, the combination with a source of energy and a polyphase induction motor connected thereto, of a liquid rheostat for governing the acceleration of said motor and embodying a regulating valve adapted to fix the height of the electrolyte and an electrically controlled device for'actuating said valve, and means directly dependent upon the attainment of a predetermined position by said valve for efi'ecting the short-circuiting of said rheostat.

57. In a control system, the combination with a source of energy, a plurality of electric motors, and means for connecting said motors to said source, of a plurality of switching devices for arranging the circuit connections of said motors for diiferent ranges of operating speeds, and means for preventing the operation of said switching devices when said connecting means occupies a predetermined position.

58. In a control system, the combination with a source of energy, an electric motor connected thereto, and a liquid rheostat for governing the operation of said motor and having a discharge valve and a regulating valve for fixing the height of the electrolyte, of means for preventing the actuation of one of said valves until the other valve occupies a predetermined position.

59. In a control system, the combination with a source of energy, an electric motor, means for connecting the motor to said source, and a liquid rheostat for governing the operation of said motor, of means for insuring the interruption of the motor circuits within said rheostat prior to the opening of said connecting means.

In testimony whereof, I have hereunto subscribed my name this 25th day of Aug,

ARTHUR J. HALL. Witnesses EARL M. BILL, B. B. HINEs.

copies of this patent may be obtained for live cents each, by addressing the "Commllsioner of Patents,

Washington, D. O." 

